Determining how biological cells respond to external factors in the environment can aid in understanding disease progression, lead to rational design strategies for tissue engineering, and contribute to understanding fundamental mechanisms of cellular function. Dynamic mechanical forces exist in vivo and are known to alter cellular response to other stimuli. However, identifying the roles multiple external factors play in regulating cell fate and function is currently impractical, as experimental techniques to mechanically stimulate cells in culture are severely limited in throughput. Hence, determining cell response to combinations of mechanical and biological factors is technically limited. In this thesis, microfabricated systems were designed, implemented and characterized to screen for the effects of mechanical stimulation in a high-throughput manner. Realizing these systems required the development of a fabrication process for precisely-aligned multilayer microstructures, and the development of a method to integrate non-traditional and clinically-relevant biomaterials into the microfabrication process. Three microfabricated platforms were developed for this application. First, an array was designed for experiments with high mechanical throughput, in which cells cultured on a surface experience a range of cyclic, uniform, equibiaxial strains. Using this array, a novel time- and strain-dependent mechanism regulating nuclear β-catenin accumulation in valve interstitial cells was identified. Second, a simpler system was designed to screen for the effects of combinatorially manipulated mechanobiological parameters on the pathological differentiation of valve interstitial cells. The results demonstrate functional heterogeneity between cells isolated from different regions of the heart valve leaflet. Last, a microfabricated platform was developed for high-throughput mechanical stimulation of cells encapsulated in a three-dimensional biomaterial, enabling the study of mechanical forces on cells in a more physiologically relevant microenvironment. Overall, these studies identified novel biological phenomena as a result of designing higher-throughput systems for the mechanical stimulation of cells.
| Identifer | oai:union.ndltd.org:TORONTO/oai:tspace.library.utoronto.ca:1807/32047 |
| Date | 18 January 2012 |
| Creators | Moraes, Christopher |
| Contributors | Simmons, Craig Alexander, Sun, Yu |
| Source Sets | University of Toronto |
| Language | en_ca |
| Detected Language | English |
| Type | Thesis |
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